Digital-analog converter, data driving circuit having the same, and display device having the same

ABSTRACT

A digital-analog converter of the disclosure converts digital image data to generate analog data signals. The digital-analog converter includes a voltage divider which generates a plurality of gamma reference voltages based on a first reference voltage and a second reference voltage; a global ramp including a plurality of gamma decoders which generates a plurality of global gamma voltages based on the gamma reference voltages; a decoder which selects one of the global gamma voltages according to the digital image data to generate the analog data signals; and a ramp controller which turns off at least some of the gamma decoders based on the digital image data.

This application is a continuation of U.S. patent application Ser. No.17/166,482, filed on Feb. 3, 2021, which claims priority to KoreanPatent Application No. 10-2020-0085697, filed on Jul. 10, 2020, and allthe benefits accruing therefrom under 35 U.S.C. § 119, the content ofwhich in its entirety is herein incorporated by reference.

BACKGROUND 1. Field

The disclosure relates to a digital-analog converter, a data drivingcircuit having the same, and a display device having the same.

2. Description of the Related Art

A display device converts an externally input digital image signal intoan analog signal using a digital-analog converter (“DAC”) and providesthe analog signal to a display panel. As resolution of the displaydevice increases, the number of bits of the digital image signalincreases. Accordingly, there is a problem that a capacity and thenumber of elements for implementing the digital-analog converterincrease and power consumption increases.

SUMMARY

An aspect of the disclosure is to provide a digital-analog convertercapable of reducing power consumption by turning off an operation of atleast some of gamma decoders included in a global ramp.

Another aspect of the disclosure is to provide a data driving circuitincluding the digital-analog converter.

Still another aspect of the disclosure is to provide a display deviceincluding the digital-analog converter.

A digital-analog converter according to embodiments of the disclosureconverts digital image data to generate analog data signals. Thedigital-analog converter includes a voltage divider which generates aplurality of gamma reference voltages based on a first reference voltageand a second reference voltage; a global ramp including a plurality ofgamma decoders which generates a plurality of global gamma voltagesbased on the gamma reference voltages; a decoder which selects one ofthe global gamma voltages according to the digital image data togenerate the analog data signals; and a ramp controller which turns offat least some of the gamma decoders based on the digital image data.

In an embodiment, the ramp controller may generate a ramp control signalby comparing most significant bits of the digital image data, and the atleast some of the gamma decoders may be turned off based on the rampcontrol signal.

In an embodiment, the ramp controller may turn off the at least some ofthe gamma decoders when all of the most significant bits are the sameduring one horizontal period.

In an embodiment, the ramp controller may turn off gamma decoders amongthe gamma decoders except for gamma decoders that generate global gammavoltages corresponding to a value of the most significant bits among theplurality of global gamma voltages.

In an embodiment, the ramp controller may generate a ramp control signalby comparing most significant bits of the digital image data andcomparing second most significant bits of the digital image data, andthe at least some of the gamma decoders may be turned off based on theramp control signal.

In an embodiment, the ramp controller may turn off the at least some ofthe gamma decoders when all of the most significant bits are the sameand all of the second most significant bits are the same.

In an embodiment, the ramp controller may turn off gamma decoders amongthe gamma decoders except for gamma decoders that generate global gammavoltages corresponding to a value of the most significant bits and avalue of the second most significant bits among the plurality of globalgamma voltages.

In an embodiment, the voltage divider may include a plurality ofresistors connected in series between a supplier of the first referencevoltage and a supplier of the second reference voltage, and generate thegamma reference voltages based on voltages divided between the firstreference voltage and the second reference voltage.

In an embodiment, the digital image data may be h bits, may includehigher bits of n bits and lower bits of m bits, and the h may correspondto the sum of the m and the n.

In an embodiment, the digital-analog converter may further include acode generator which generates a digital code corresponding to the lowerbits of the digital image data, and the global ramp may generate theglobal gamma voltages in response to the digital code.

In an embodiment, the decoder may generate the analog data signals inresponse to an input code corresponding to the higher bits of thedigital image data.

In an embodiment, the second reference voltage may be a ground voltage.

A data driving circuit according to embodiments of disclosure includes adigital-analog converter which converts digital image data to generateanalog data signals; and a buffer which outputs data voltages to datalines based on the analog data signals. The digital-analog converterincludes a voltage divider which generates a plurality of gammareference voltages based on a first reference voltage and a secondreference voltage; a global ramp including a plurality of gamma decoderswhich generates a plurality of global gamma voltages based on the gammareference voltages; a decoder which selects one of the global gammavoltages according to the digital image data to generate the analog datasignals; and a ramp controller which turns off at least some of thegamma decoders based on the digital image data.

In an embodiment, the ramp controller may generate a ramp control signalby comparing most significant bits of the digital image datacorresponding to the data lines, respectively, and the at least some ofthe gamma decoders may be turned off based on the ramp control signal.

In an embodiment, the ramp controller may turn off gamma decoders amongthe gamma decoders except for gamma decoders that generate global gammavoltages corresponding to a value of the most significant bits among theplurality of global gamma voltages, when all of the most significantbits are the same.

In an embodiment, the ramp controller may generate a ramp control signalby comparing most significant bits of the digital image datacorresponding to the data lines, respectively, and comparing second mostsignificant bits of the digital image data, and the at least some of thegamma decoders may be turned off based on the ramp control signal.

In an embodiment, the ramp controller may turn off gamma decoders amongthe gamma decoders except for gamma decoders that generate global gammavoltages corresponding to a value of the most significant bits and avalue of the second most significant bits among the plurality of globalgamma voltages, when all of the most significant bits are the same andall of the second most significant bits are the same.

A display device according to embodiments of the disclosure includes adisplay panel including a plurality of pixels, a data driving circuitwhich provides data signals to the pixels through data lines; and atiming controller which provides image data to the data driving circuit.The data driving circuit includes a digital-analog converter whichconverts the image data of a digital format to generate the analog datasignals of an analog format; and a buffer which outputs the data signalsto the data lines. The digital-analog converter includes a voltagedivider which generates a plurality of gamma reference voltages based ona first reference voltage and a second reference voltage; a global rampincluding a plurality of gamma decoders which generates a plurality ofglobal gamma voltages based on the gamma reference voltages; and adecoder which selects one of the global gamma voltages according to theimage data to generate the analog data signals. The timing controllerturns off at least some of the gamma decoders based on the image data.

In an embodiment, the timing controller may include a ramp controllerwhich generates a ramp control signal by comparing most significant bitsof the image data corresponding to the data lines, respectively, and theat least some of the gamma decoders may be turned off based on the rampcontrol signal.

In an embodiment, the timing controller may include a ramp controllerwhich generates a ramp control signal by comparing most significant bitsof the image data corresponding to the data lines, respectively, andcomparing second most significant bits of the digital image data, andthe at least some of the gamma decoders may be turned off based on theramp control signal.

The digital-analog converter according to embodiments of the disclosuremay reduce power consumption by turning off an operation of at leastsome of gamma decoders included in a global ramp in one horizontalperiod by comparing the most significant bits of image datacorresponding to channels, respectively.

However, an effect of the disclosure is not limited to theabove-described effect, and may be variously expanded without departingfrom the spirit and scope of the disclosure.

BRIEF DESCRIPTION OF THE DRAWINGS

The above and other features of the invention will become more apparentby describing in further detail exemplary embodiments thereof withreference to the accompanying drawings, in which:

FIG. 1 is a block diagram illustrating a display device according toembodiments of the disclosure;

FIG. 2 is a circuit diagram illustrating an example of a pixel includedin the display device of FIG. 1 ;

FIG. 3 is a diagram for describing image data according to embodimentsof the disclosure;

FIG. 4 is a block diagram illustrating a data driving circuit accordingto embodiments of the disclosure;

FIGS. 5 to 9 are diagrams for describing a digital-analog converteraccording to embodiments of the disclosure;

FIGS. 10A and 10B are diagrams for describing examples of an operationof the digital-analog converter according to FIGS. 5 to 9 ;

FIGS. 11 and 12 are diagrams for describing a digital-analog converteraccording to embodiments of the disclosure; and

FIGS. 13A to 13D are diagrams for describing examples of an operation ofthe digital-analog converter according to FIGS. 11 and 12 .

FIG. 14 is a block diagram illustrating a display device according toembodiments of the disclosure.

DETAILED DESCRIPTION

The disclosure may be modified in various manners and have variousforms. Therefore, specific embodiments will be illustrated in thedrawings and will be described in detail in the specification. However,it should be understood that the disclosure is not intended to belimited to the disclosed specific forms, and the disclosure includes allmodifications, equivalents, and substitutions within the spirit andtechnical scope of the disclosure.

Similar reference numerals are used for similar components in describingeach drawing. In the accompanying drawings, the dimensions of thestructures are shown enlarged from the actual dimensions for the sake ofclarity of the disclosure. Terms of “first”, “second”, and the like maybe used to describe various components, but the components should not belimited by the terms. The terms are used only for the purpose ofdistinguishing one component from another component. For example,without departing from the scope of the disclosure, a first componentmay be referred to as a second component, and similarly, a secondcomponent may also be referred to as a first component. The singularexpressions include plural expressions unless the context clearlyindicates otherwise.

It should be understood that in the present application, a term of“include”, “have”, or the like is used to specify that there is afeature, a number, a step, an operation, a component, a part, or acombination thereof described in the specification, but does not excludea possibility of the presence or addition of one or more other features,numbers, steps, operations, components, parts, or combinations thereofin advance.

The terminology used herein is for the purpose of describing particularembodiments only and is not intended to be limiting. As used herein, thesingular forms “a,” “an,” and “the” are intended to include the pluralforms, including “at least one,” unless the content clearly indicatesotherwise. “At least one” is not to be construed as limiting “a” or“an.” “or” means “and/or.” As used herein, the term “and/or” includesany and all combinations of one or more of the associated listed items.In addition, a case where a portion is “connected” to another portion,the case includes not only a case where the portion is directlyconnected to the other portion but also a case where the portion isconnected to the other portion with another element interposedtherebetween.

Hereinafter, embodiments of the disclosure will be described in detailwith reference to the accompanying drawings.

FIG. 1 is a block diagram illustrating a display device according toembodiments of the disclosure.

Referring to FIG. 1 , the display device 1000 may include a displaypanel 100, a timing controller 200, a scan driver 300 (or a scan drivingcircuit), and a data driver 400 (or a data driving circuit).

The display panel 100 may include pixels. Each pixel PXij may beconnected to corresponding data line and scan line. i and j may beintegers greater than 0. The pixel PXij may refer to a pixel in which ascan transistor is connected to an i-th scan line and a j-th data line.Each pixel PXij may receive voltages of first power VDD and second powerVSS from the outside. Here, the first power VDD and the second power VSSmay be voltages required for an operation of the pixels. For example,the first power VDD may have a voltage level higher than a voltage levelof the second power VSS.

The timing controller 200 may generate a data control signal DCS forcontrolling the data driver 400 and a scan control signal SCS forcontrolling the scan driver 300. The data control signal DCS may includea clock signal supplied to a register of the data driver 400, a linelatch signal supplied to a latch, and the like. In addition, the timingcontroller 200 may provide image data DATA of a digital format to thedata driver 400.

The scan driver 300 may supply scan signals to the pixels through scanlines SL1, SL2, . . . , and SLp in response to the scan control signalSCS. p may be an integer greater than 0.

The data driver 400 may convert the image data DATA of the digitalformat into data signals (data voltages) of an analog format in responseto the data control signal DCS, and may supply the data signals (datavoltages) to the pixels through data lines DL1, DL2, . . . , and DLq. qmay be an integer greater than 0.

The data driver 400 may receive a reference voltage VGM from the outside(for example, a gamma voltage generator), convert the digital image dataDATA into an analog signal, that is, a grayscale voltage, and supply theanalog signal to the pixels as a data signal (data voltage).

FIG. 2 is a circuit diagram illustrating an example of the pixelincluded in the display device of FIG. 1 .

Referring to FIG. 2 , the pixel PXij may include a light emittingelement LD and a driving circuit DC connected to the light emittingelement LD to drive the light emitting element LD.

A first electrode (for example, an anode electrode) of the lightemitting element LD may be supplied with the first power VDD via thedriving circuit DC, and a second electrode (for example, a cathodeelectrode) of the light emitting element LD may be supplied with thesecond power VSS. The light emitting element LD may emit light at aluminance corresponding to a driving current amount flowing through thelight emitting element LD and controlled by the driving circuit DC.

The light emitting device LD may be selected as an organic lightemitting diode. In another embodiment, the light emitting element LD maybe selected as an inorganic light emitting diode, such as a micro lightemitting diode (“LED”) or a quantum dot light emitting diode. In stillanother embodiment, the light emitting element LD may be an elementconfigured of an organic material and an inorganic material incombination. In FIG. 2 , the pixel PXij includes a single light emittingelement LD. However, in another embodiment, the pixel PXij may include aplurality of light emitting elements, and the plurality of lightemitting elements may be connected to each other in series, in parallel,or in series and parallel.

The first power VDD and the second power VSS may have different values.For example, a voltage value of the first power VDD may be greater thana voltage value of the second power VSS.

The driving circuit DC may include a first transistor T1, a secondtransistor T2, and a storage capacitor Cst.

A first electrode of the first transistor T1 (a driving transistor) maybe supplied with the first power VDD, and a second electrode of thefirst transistor T1 may be electrically connected to the first electrode(for example, the anode electrode) of the light emitting element LD. Agate electrode of the first transistor T1 may be connected to a firstnode N1. The first transistor T1 may control the driving current amountsupplied to the light emitting element LD in correspondence with a datasignal supplied to the first node N1 through the data line DLj.

A first electrode of the second transistor T2 (a switching transistor)may be connected to the data line DLj, and the second electrode of thesecond transistor T2 may be connected to the first node N1. A gateelectrode of the second transistor T2 may be connected to the scan lineSLi.

The second transistor T2 may be turned on when a scan signal of avoltage (for example, a gate-on voltage) at which the second transistorT2 may be turned on is supplied from the scan line SLi, to electricallyconnect the data line DLj and the first node N1. At this time, the datasignal of a corresponding frame may be supplied to the data line DLj,and thus the data signal may be transferred to the first node N1. Avoltage corresponding to the data signal transferred to the first nodeN1 may be stored in the storage capacitor Cst.

One electrode of the storage capacitor Cst may be connected to the firstnode N1, and another electrode of the storage capacitor Cst may beconnected to the first electrode of the light emitting element LD. Thestorage capacitor Cst may be charged with a voltage corresponding to thedata signal supplied to the first node N1, and may maintain the chargedvoltage until the data signal of the next frame is supplied.

FIG. 2 shows a relatively simple pixel PXij for convenience ofdescription, and a structure of the driving circuit DC may be variouslychanged in another embodiment. For example, the driving circuit DC mayfurther include other circuit elements such as various transistors, forexample, a compensation transistor for compensating for a thresholdvoltage of the first transistor T1, an initialization transistor forinitializing the first node N1, and/or a light emission controltransistor for controlling a light emission time of the light emittingelement LD, and a boosting capacitor for boosting the voltage of thefirst node N1.

In addition, in FIG. 2 , the transistors included in the driving circuitDC, for example, the first and second transistors T1 and T2 are N-typetransistors, but the disclosure according to the invention is notlimited thereto. That is, at least one of the first and secondtransistors T1 and T2 included in the driving circuit DC may be changedto a P-type transistor in another embodiment.

FIG. 3 is a diagram for describing image data according to embodimentsof the disclosure.

Referring to FIGS. 1 and 3 , the image data DATA of the digital formatsupplied from the timing controller 200 to the data driver 400 may beimage data of h bits. h may be an integer greater than 0. When the imagedata DATA is the h bits, the display device 1000 according toembodiments of the disclosure may express 2 ^(h) grayscales, that is, 0grayscale to 2 ^(h)- 1 grayscale. In FIG. 3 , image data DATA of 10 bitsis shown as an example, and in the following description, descriptionwill be given under an assumption of the image data DATA of 10 bitsunless otherwise specified.

In an embodiment, the image data DATA according to embodiments of thedisclosure may include higher bits HB of n bits including the mostsignificant bit MSB and lower bits LB of m bits including the leastsignificant bit LSB. Here, the most significant bit MSB may correspondto a bit position having the highest value of the image data DATA, andthe least significant bit LSB may correspond to a bit position havingthe lowest value of the image data DATA. Here, n may be an integergreater than 0, and m may be an integer greater than 0. In addition, inembodiments of the disclosure, the higher bits HB may be n bits (e.g.,HB<9> to HB<4>) as bit positions having a high value of the image dataDATA, and the lower bits LB may be m bits (e.g., LB<3> to LB<0>) as bitpositions having a low value of the image data DATA. Here, ‘h=n+m’ maybe satisfied. In FIG. 3 , the higher bits HB of 6 bits and the lowerbits LB of 4 bits are shown as an example. However, in an embodiment,the number of bits included in each of the higher bits HB and the lowerbits LB may be variously set. Hereinafter, description will be givenunder an assumption that the image data DATA includes the higher bits HBof 6 bits and the lower bits LB of 4 bits unless otherwise specified.

FIG. 4 is a block diagram illustrating a data driving circuit accordingto embodiments of the disclosure, FIGS. 5 to 9 are diagrams fordescribing a digital-analog converter according to embodiments of thedisclosure, and FIGS. 10A and 10B are diagrams for describing examplesof an operation of the digital-analog converter according to FIGS. 5 to9 .

Referring to FIGS. 1, 3, and 4 , the data driver 400 (or the datadriving circuit) may include a register 410, a latch 420, adigital-analog converter 430, and a buffer 440.

The register 410 may sequentially activate latch clock signals insynchronization with a clock signal CLK and provide latch clock signalsto the latch 420. The register 410 may include a plurality of shiftregisters.

The latch 420 may receive the latch clock signals sequentially providedfrom the register 410, and sample and latch the image data DATA of thedigital format in synchronization with the latch clock signals. Inaddition, the latch 420 may provide the latched digital image data DATAto the digital-analog converter 430 in response to the line latchsignal.

The digital-analog converter 430 may convert the digital image data DATAprovided from the latch 420 into an analog signal. The digital-analogconverter 430 may receive the reference voltage VGM supplied from thegamma voltage generator, convert the digital image data DATA into ananalog signal (i.e., a grayscale voltage), and provide the convertedanalog signal to the buffer 440 as the data signal (the data voltage).In embodiments of the disclosure, description will be given based on onechannel CH among a plurality of channels and under an assumption thatthe digital-analog converter 430 is a 10-bit digital-analog converter430. The image data DATA of 10 bits shown in FIG. 3 may be input to the10-bit digital-analog converter 430.

In an embodiment, the digital-analog converter 430 may include a voltagedivider 431, a global ramp 432, a code generator 433, and a decoder 435.

The code generator 433 may generate a digital code CODE by counting anoscillation signal having a divided frequency generated by a frequencydivider. For example, the code generator 433 may be implemented as acounter. For example, the code generator 433 may count the number ofrising or falling edges of the oscillation signal and generate thedigital code CODE of m bits corresponding to a count result. The digitalcode CODE may be determined according to the lower bits LB of the imagedata DATA. Accordingly, hereinafter, it is assumed that the codegenerator 433 is a 4-bit counter, and in this case, the code generator433 may output a 4-bit digital code CODE that is incremented by 1 perevery period of the oscillation signal divided from 0 (for example,0000) to 15 (for example, 1111). The output digital code CODE may beprovided to the global ramp 432.

The voltage divider 431 may receive the reference voltage VGM, which isa gamma power voltage supplied from the gamma voltage generator, andgenerate a plurality of gamma reference voltages for expressing apredetermined grayscale using the reference voltage VGM. In response tothe image data DATA of 10 bits, the voltage divider 431 may generate 2¹⁰, that is, 1024 gamma reference voltages.

The global ramp 432 may receive the plurality of gamma referencevoltages from the voltage divider 431 and generate global gamma voltagesin response to the digital code CODE supplied from the code generator433.

Referring to FIG. 5 additionally, to specifically describe the voltagedivider 431 and the global ramp 432, the voltage divider 431 maygenerate a plurality of gamma reference voltages V0 to V1023 forexpressing a predetermined grayscale based on the reference voltage VGM.

In an embodiment, the voltage divider 431 may include 2 k gamma voltagedividers GVD[1] to GVD[2 k], and the gamma voltage dividers GVD[1] toGVD[2 k] may be connected in series between a supplier of the referencevoltage VGM (i.e., a first reference voltage) and a supplier of a groundvoltage (i.e., a second reference voltage). In addition, each of thegamma voltage dividers GVD[1] to GVD[2 k] may include a plurality ofresistors connected in series. Each of the gamma voltage dividers GVD[1]to GVD[2 k] may generate r gamma reference voltages through a voltagedistribution of the resistor. For example, the first gamma voltagedivider GVD[1] may generate r gamma reference voltages V0 to Vr-1through a voltage distribution of the resistor using the plurality ofresistors connected in series. Accordingly, the voltage divider 431 maygenerate the plurality of gamma reference voltages V0 to V1023. Here, kand r are natural numbers.

In FIGS. 5 to 10B, it is assumed that r is 2⁴, that is, 16, and 2 k is1024/16, that is, 64(=2⁶), in correspondence with the lower bits LB of 4bits and the digital code CODE of 4 bits.

The global ramp 432 may receive the gamma reference voltages V0 toV1023, and may generate 2 k global gamma voltages A[1] to A[2k] of astep wave form, in which each of 2 k global gamma voltages A[1] to A[2k]is sequentially rising or falling. Here, the global gamma voltages A[1]to A[2k] may be commonly provided to each channel CH.

In an embodiment, the global ramp 432 may include 2 k gamma decodersDEC[1] to DEC[2k] corresponding to the 2 k gamma voltage dividers GVD[1]to GVD[2k], respectively. Each of the gamma decoders DEC[1] to DEC[2k]may receive r gamma reference voltages among the plurality of gammareference voltages V0 to V1023 through a corresponding gamma voltagedivider, and may be implemented as an r bit decoder that outputs oneglobal gamma voltage in correspondence with the digital code CODE of mbits (e.g., the digital code CODE of 4 bits).

In an embodiment, for example, description is given based on the firstgamma decoder DEC[1] with reference to FIG. 6 additionally. The firstgamma decoder DEC[1] may include a plurality of switches receiving rgamma reference voltages V0 to Vr-1 from the first gamma voltage dividerGVD[1]. Here, one corresponding switch among the plurality of switchesmay be sequentially turned on based on the digital code CODE of m bit,which is sequentially rising (or falling). Accordingly, the first gammadecoder DEC[1] may output the first global gamma voltage A[1] of a stepwave form which is sequentially rising (or falling) by sequentiallyoutputting the r gamma reference voltages V0 to Vr-1.

Accordingly, the first gamma decoder DEC[1] may receive the r gammareference voltages V0 to Vr-1 from the first gamma voltage dividerGVD[1] to output the first global gamma voltage A[1], the k-th gammadecoder DEC[k] may receive the r gamma reference voltages from the k-thgamma voltage divider GVD[k] to output the k-th global gamma voltageA[k], the (k+1)-th gamma decoder DEC[k+1] may receive the r gammareference voltages from the (k+1)-th gamma voltage divider GVD[k+1] tooutput the (k+1)-th global gamma voltage A[k+1], and the 2 k-th gammadecoder DEC[2k] may receive the r gamma reference voltages V1024-r toV1023 from the 2 k-th gamma voltage divider GVD[2k] to output the 2 k-thglobal gamma voltage A[2k].

The digital code CODE of m bits (e.g., the digital code CODE of 4 bits)may have a rising period (or a falling period) corresponding to onehorizontal period 1H and sequentially increase (or decrease). Forexample, the digital code CODE of 4 bits may increase from 0 (forexample, 0000) to 15 (for example, 1111) by 1 at a time interval of 1H/r(or 1H/16) during 1 horizontal period 1H. Accordingly, as shown in FIG.6 , each of the gamma decoders DEC[1] to DEC[2k] may generate the globalgamma voltage (for example, the first global gamma voltage A[1] of FIG.5 ) of a step wave form sequentially rising at a time interval of 1H/rduring one horizontal period 1H.

In an embodiment, the global ramp 432 may be divided into a first subglobal ramp 432 a including the k gamma decoders DEC[1] to DEC[k] and asecond sub global ramp 432 a including the k gamma decoders DEC[k+1] toDEC[2k].

In an embodiment, the global ramp 432 may turn off an operation of oneof the first sub global ramp 432 a and the second sub global ramp 432 bbased on a ramp control signal RCS. A configuration in which the globalramp 432 turns off the operation of one of the first and second subglobal ramps 432 a and 432 b based on the ramp control signal RCS isspecifically described with reference to FIGS. 8 to 10B.

The decoder 435 may receive the global gamma voltages A[1] to A[2k] fromthe global ramp 432, and may output one global gamma voltagecorresponding to each channel CH to the buffer 440 as the data signal(the data voltage). Here, the one global gamma voltage is chosen amongthe global gamma voltages A[1] to A[2k].

Referring to FIG. 7 additionally to specifically describe the decoder435, the decoder 435 may be implemented as an n bit decoder incorrespondence with each channel CH. The configuration of the decoder435 may be determined according to the higher bits HB of the image dataDATA. Accordingly, hereinafter, it is assumed that the decoder 435 is a6-bit decoder. Since the decoder 435 is the 6-bit decoder, input codesD<4> to D<9> of 6 bits may be input to the decoder 435 as an input code.

The decoder 435 may include selectors 4351, 4352, 4353, 4354, 4355, and4356, of which each is configured of a switch. For example, the switchmay be implemented as a transistor that functions as a switchingfunction. However, this is exemplary, and a configuration of the decoder435 according to the invention is not limited thereto.

The selectors 4351, 4352, 4353, 4354, 4355, and 4356 may be connected toeach other (e.g., sequentially connected), and the switches included inthe selectors 4351, 4352, 4353, 4354, 4355, and 4356 may be turned on orturned off in response to the input codes D<4> to D<9>. The selectors4351, 4352, 4353, 4354, 4355, and 4356 may be operated in response tothe input codes D<4> to D<9>, respectively.

The decoder 435 may select one of the global gamma voltages A[1] toA[2k] in response to the input codes D<4> to D<9> of 6 bits. At thistime, the decoder 435 may select one global gamma voltage insynchronization with a timing of a voltage level corresponding to thechannel CH among the global gamma voltages of one step wave form.

In an embodiment, for example, assuming that a voltage of a firstvoltage level V0 is selected among voltage levels of the first globalgamma voltage A[1] of a sequentially rising step wave form, 0 (forexample, 0000) is applied to the first gamma decoder DEC[1]. Therefore,the decoder 435 may select the first global gamma voltage A[1] of thefirst voltage level V0 in response to the input bits D<4> to D<9> of 2⁶(for example, 111111) in synchronization with a timing at which thefirst global gamma voltage A[1] of the first voltage level V0 is output.At this time, a node to which the first global gamma voltage A[1] isapplied and an output node OP may be connected by the switches turned onin response to the input bits D<4> to D<9> of 2⁶ (for example, 111111).Accordingly, the first global gamma voltage A[1] of the first voltagelevel V0 may be selected.

The buffer 440 may include a channel switch 441, a capacitor 442, and anoutput buffer 443.

The channel switch 441 may provide the data signal output from thedigital-analog converter 430 (or the decoder 435) to the output buffer443 in response to a switch control signal SON corresponding to acorresponding channel CH and supplied in one horizontal period 1H unit.

The capacitor 442 may be disposed between an input terminal of theoutput buffer 443 and the ground voltage to reduce noise of the datasignal.

The output buffer 443 may output the data signal to a data line DLconnected in correspondence with a corresponding channel CH.

As described above, the digital-analog converter 430 according toembodiments of the disclosure includes the global ramp 432 thatgenerates the global gamma voltages A[1] to A[2k] commonly provided toeach channel CH. Therefore, the digital-analog converter 430 (or thedata driving circuit 400) may be implemented in a relatively small area.

In addition, the digital-analog converter 430 according to embodimentsof the disclosure may reduce power consumption by comparing the mostsignificant bits MSB of the image data DATA corresponding to eachchannel CH and turning off an operation of at least some of the gammadecoders DEC[1] to DEC[2k] included in the global ramp 432 according tothe comparison result. For example, the digital-analog converter 430 mayfurther include the ramp controller 434, and the ramp controller 434 maygenerate the ramp control signal RCS by comparing the most significantbits MSB of the image data DATA corresponding to each channel CH. Inaddition, the global ramp 432 may turn off an operation of one of thefirst sub global ramp 432 a and the second sub global ramps 432 b. Thefirst sub global ramp 432 a may include the first to k-th gamma decodersDEC[1] to DEC[k], and the second sub global ramps 432 b may include the(k+1)-th to 2 k gamma decoders DEC[k+1] to DEC[2k].

Referring to FIG. 8 additionally to specifically describe this, the rampcontroller 434 may generate the ramp control signal RCS based on mostsignificant bits HB<9>#1 to HB<9>#q corresponding to each channel CH. InFIG. 8 , each of the most significant bits HB<9>#1 to HB<9>#q maycorrespond to a bit position having the highest value among the bitpositions of each of the image data DATA. The most significant bitsHB<9>#1 to HB<9>#q may have a value of 0 or 1 at the bit position havingthe highest value.

In an embodiment, the ramp controller 434 may generate the ramp controlsignal RCS by comparing the most significant bits HB<9>#1 to HB<9>#q.The ramp controller 434 may determine gamma decoders to be turned offamong the gamma decoders DEC[1] to DEC[2k] included in the global ramp432 by comparing the most significant bits HB<9>#1 to HB<9>#q and thengenerate the ramp control signal RCS based on the determination. Forexample, the ramp controller 434 may be configured as a single logiccircuit or a combination of a plurality of logic circuits to compare themost significant bits HB<9>#1 to HB<9>#q.

When all of the most significant bits HB<9>#1 to HB<9>#q are the same,the ramp controller 434 may generate the ramp control signal RCS to turnoff the operation of one of the first sub global ramp 432 a and thesecond sub global ramp 432 b. For example, when all of the mostsignificant bits HB<9>#1 to HB<9>#q have a value of 1, the rampcontroller 434 may turn off the operation of the second sub global ramp432 b, and when all of the most significant bits HB<9>#1 to HB<9>#q havea value of 0, the ramp controller 434 may turn off the operation of thefirst sub global ramp 432 a.

Referring to FIG. 9 as an example, the ramp controller 434 may includean exclusive-OR circuit 4341, a comparator 4342, and a ramp controlsignal generator 4343.

The exclusive-OR circuit 4341 may include a plurality of XOR gates. Eachof the plurality of XOR gates may be implemented as a 2-input structure,and receive two most significant bits among the most significant bitsHB<9>#1 to HB<9>#q. Here, the exclusive-OR circuit 4341 may include(q-1)X(q-2)X . . . X2X1=(q-1)! XOR gates to compare all two sub-sets ofthe most significant bits HB<9>#1 to HB<9>#q. That is, the number of XORgates used here may be (q-1)!.

Each of the plurality of XOR gates in the exclusive-OR circuit 4341 mayoutput a value of 0 when both of the two input most significant bitshave the same value (e.g., a value of 0 or a value of 1), and may outputa value of 1 when the both of the two input most significant bits havedifferent values (that is, one of the input most significant bits has avalue of 0 and the other of the input most significant bits has a valueof 1).

The comparator 4342 may receive output signals output from theexclusive-OR circuit 4431 and one most significant bit (for example, thefirst most significant one HB<9>#1) among the most significant bitsHB<9>#1 to HB<9>#q, and output a comparison result signal RS.

The ramp control signal generator 4343 may generate the ramp controlsignal RCS based on the comparison result signal RS.

In an embodiment, when all of the most significant bits HB<9>#1 toHB<9>#q are the same as the value of 1 in correspondence with onehorizontal period 1H, the ramp control signal generator 4343 maygenerate the ramp control signal RCS for turning off the operation ofthe second sub global ramp 432 b during the corresponding horizontalperiod, based on the comparison result signal RS.

In an embodiment, for example, referring to FIG. 10A, when all of themost significant bits HB<9>#1 to HB<9>#q of the image data DATAcorresponding to the channels CH have the value of 1, only the firstswitch SW1 of the switches SW1 and SW2 included in the selector 4356corresponding to the most significant bits HB<9>#1 to HB<9>#q may beturned on in response to the input code D<9>having a value of 1. In thiscase, the second switch SW2 may maintain a turn-off state. In this case,since the second switch SW2 maintains the turn-off state, the globalgamma voltages A[k+1] to A[2k] output by the second sub global ramp 432b are not output to the buffer 440.

Accordingly, in order to prevent unnecessary power consumption due tothe operation of the second sub global ramp 432 b in the correspondinghorizontal period, the ramp control signal generator 4343 may generatethe ramp control signal RCS for turning off the operation of the secondsub global ramp 432 b. In this case, the global ramp 432 may turn offthe operation of the second sub global ramp 432 b based on the rampcontrol signal RCS provided from the ramp controller 434 (or the rampcontrol signal generator 4343).

In an embodiment, when all of the most significant bits HB<9>#1 toHB<9>#q are the same as the value of 0 in correspondence with onehorizontal period 1H, the ramp control signal generator 4343 maygenerate the ramp control signal RCS for turning off the operation ofthe first sub global ramp 432 a during the corresponding horizontalperiod, based on the comparison result signal RS.

In an embodiment, for example, referring to FIG. 10B, when all of themost significant bits HB<9>#1 to HB<9>#q of the image data DATAcorresponding to the channels CH have the value of 0, only the secondswitch SW2 of the switches SW1 and SW2 included in the selector 4356corresponding to the most significant bits HB<9>#1 to HB<9>#q may beturned on in response to the input code D<9>having a value of 0. In thiscase, the first switch SW1 may maintain a turn-off state. In this case,since the first switch SW1 maintains the turn-off state, the globalgamma voltages A[1] to A[k] output by the first sub global ramp 432 aare not output to the buffer 440.

Accordingly, in order to prevent unnecessary power consumption due tothe operation of the first sub global ramp 432 a in the correspondinghorizontal period, the ramp control signal generator 4343 may generatethe ramp control signal RCS for turning off the operation of the firstsub global ramp 432 a. In this case, the global ramp 432 may turn offthe operation of the first sub global ramp 432 a based on the rampcontrol signal RCS provided from the ramp controller 434 (or the rampcontrol signal generator 4343).

On the other hand, when at least one of the most significant bitsHB<9>#1 to HB<9>#q has a different value from the other most significantbits, since both of the first and second sub global ramps 432 a and 432b are to be operated during one horizontal period, the ramp controlsignal generator 4343 may generate a ramp control signal RCS foroperating the both of the first and second sub global ramps 432 a and432 b or may not generate the ramp control signal RCS.

In an embodiment, the global ramp 432 may turn off the operation of thefirst sub global ramp 432 a or the second sub global ramp 432 b using amethod of cutting off power supplied to the first sub global ramp 432 aor the second sub global ramp 432 b, based on the ramp control signalRCS.

In FIG. 9 , a configuration in which the ramp controller 434 isimplemented as the plurality of XOR gates to compare the mostsignificant bits HB<9>#1 to HB<9>#q is shown and described, but this isexemplary and the present disclosure according to the invention is notlimited thereto. The ramp controller 434 according to embodiments of thedisclosure may be implemented in a form in which a single logic circuitsuch as an AND gate, or an OR gate, or a plurality of logic circuits inaddition to the XOR gate is combined, to compare the most significantbits HB<9>#1 to HB<9>#q.

As described with reference to FIGS. 3 to 10B, the digital-analogconverter 430 according to embodiments of the disclosure may reducepower consumption by turning off the operation of at least some of thegamma decoders DEC[1] to DEC[2k] included in the global ramp 432 in onehorizontal period by comparing the most significant bits MSB of theimage data DATA corresponding to the channels CH, respectively.

FIGS. 11 and 12 are diagrams for describing a digital-analog converteraccording to embodiments of the disclosure, and FIGS. 13A to 13D arediagrams for describing examples of an operation of the digital-analogconverter according to FIGS. 11 and 12 .

Referring to FIGS. 11 and 12 , the digital-analog converter 430according to FIGS. 11 and 12 is substantially the same as or similar tothe digital-analog converter 430 according to FIGS. 5 to 9 except for aconfiguration in which a global ramp 432′ of FIG. 11 is divided intofirst to fourth sub global ramps 432 a′, 432 b′, 432 c′, and 432 d′, anda ramp controller 434′ of FIG. 12 further receives second mostsignificant bits HB<8>#1 to HB<8>#q. Here, the second most significantbits are the higher bits HB<8>#1 to HB<8>#q of a bit position closest tothe bit position of the most significant bit MSB. Therefore, repetitivedescription is omitted.

In an embodiment, the global ramp 432′ may be divided into the first subglobal ramp 432 a′ including k gamma decoders DEC[1] to DEC[k], thesecond sub global ramp 432 b′ including k gamma decoders DEC[k+1] toDEC[2k], the third sub global ramp 432 c′ including k gamma decodersDEC[2 k+1] to DEC[3k], and the fourth sub global ramp 432 d′ including kgamma decoders DEC[3 k+1] to DEC[4k]. In FIGS. 11 to 13D, it is assumedthat 4 k is 1024/16, that is, 64(=2⁶).

In an embodiment, the global ramp 432′ may turn off an operation of atleast one of the first sub global ramp 432 a′, the second sub globalramp 432 b′, the third sub global ramp 432 c′, and the fourth sub globalramps 432 d′ based on a ramp control signal RCS_1.

The ramp controller 434′ may generate the ramp control signal RCS_1,based on a comparison result of the most significant bit MSB of theimage data DATA corresponding to each channel CH and a comparison resultof the second most significant bits.

As shown in FIG. 12 , the ramp controller 434′ may generate the rampcontrol signal RCS_1 based on the most significant bits HB<9>#1 toHB<9>#q and the second most significant bits HB<8>#1 to HB<8>#q.

In an embodiment, the ramp controller 434′ may generate the ramp controlsignal RCS_1 by comparing the most significant bits HB<9>#1 to HB<9>#qand comparing the second most significant bits HB<8>#1 to HB<8># q. Theramp controller 434′ may generate the ramp control signal RCS_1 bydetermining the gamma decoders to be turned off among the gamma decodersDEC[1] to DEC[4k] included in the global ramp 432′, based on thecomparison result for the most significant bits HB<9>#1 to HB<9>#q andthe comparison result for the second most significant bits HB<8>#1 toHB<8>#q.

When all of the most significant bits HB<9>#1 to HB<9>#q are the sameand all of the second most significant bits HB<8>#1 to HB<8>#q are thesame, the ramp controller 434′ may generate a ramp control signal RCS_1for turning off remaining sub global ramps except for one of the firstto fourth sub global ramps 432 a′, 432 b′, 432 c′, and 432 d′.

In an embodiment, when all of the most significant bits HB<9>#1 toHB<9>#q have a value of 1 and all of the second most significant bitsHB<8>#1 to HB<8>#q have a value of 1, the ramp controller 434′ may turnoff the operation of the second to fourth sub global ramps 432 b′, 432c′, and 432 d′ except for the first sub global ramp 432 a′ as shown inFIG. 13A. In addition, when all of the most significant bits HB<9>#1 toHB<9>#q have a value of 1 and all of the second most significant bitsHB<8>#1 to HB<8>#q have a value of 0, the ramp controller 434′ may turnoff the operation of the first, third, and fourth sub global ramps 432a′, 432 c′, and 432 d′ except for the second sub global ramp 432 b′ asshown in FIG. 13B. In addition, when all of the most significant bitsHB<9>#1 to HB<9>#q have a value of 0 and all of the second mostsignificant bits HB<8>#1 to HB<8>#q have a value of 1, the rampcontroller 434′ may turn off the operation of the first, second, andfourth sub global ramps 432 a′, 432 b′, and 432 d′ except for the thirdsub global ramp 432 c′ as shown in FIG. 13C. In addition, when all ofthe most significant bits HB<9>#1 to HB<9>#q have a value of 0 and allof the second most significant bits HB<8>#1 to HB<8>#q have a value of0, the ramp controller 434′ may turn off the operation of the first tothird sub global ramps 432 a′, 432 b′, and 432 c′ except for the fourthsub global ramp 432 d′ as shown in FIG. 13D.

In an embodiment, for example, referring to FIG. 13A, when all of themost significant bits HB<9>#1 to HB<9>#q of the image data DATAcorresponding to the channels CH have a value of 1, only the firstswitch SW1 of the switches SW1 and SW2 included in the selector 4356corresponding to the most significant bits HB<9>#1 to HB<9>#q may beturned on in response to the input code D<9> having a value of 1. Inthis case, the second switch SW2 may maintain a turn-off state. In thiscase, since the second switch SW2 maintains the turn-off state, globalgamma voltages A[2 k+1] to A[4k] output by the third and fourth subglobal ramps 432 c′ and 432 d′ are not output to the buffer 440.

In addition, when all of the second most significant bits HB<8>#1 toHB<8>#q of the image data DATA corresponding to the channels CH have avalue of 1, only third and fifth switches SW3 and SW5 of switches SW3,SW4, SW5, and SW6 included in the selector 4355 corresponding to thesecond most significant bits HB<8>#1 to HB<8>#q may be turned on inresponse to the input code D<8> having a value of 1. In this case, thefourth and sixth switches SW4 and SW6 may maintain a turn-off state. Inthis case, since the fourth and sixth switches SW4 and SW6 maintain theturn-off state, the global gamma voltages [k+1] to A[2k] and A[3 k+1] toA[4k] output by the second and fourth sub global ramps 432 b′ and 432 d′are not output to the buffer 440.

In sum, the global gamma voltages A[k+1] to A[4k] output by the secondto fourth sub global ramps 432 b′, 432 c′, and 432 d′ in a correspondinghorizontal period are not output to the buffer 440.

Accordingly, in order to prevent unnecessary power consumption due tothe operation of the second to fourth sub global ramps 432 b′, 432 c′,and 432 d′ in the corresponding horizontal period, the ramp controller434′ may generate the ramp control signal RCS_1 for turning off theoperation of the second to fourth sub global ramps 432 b′, 432 c′, and432 d′. In this case, the global ramp 432 may turn off the operation ofthe second to fourth sub global ramps 432 b′, 432 c′, and 432 d′ basedon the ramp control signal RCS_1 provided from the ramp controller 434′.

As another example, referring to FIG. 13B, when all of the mostsignificant bits HB<9>#1 to HB<9>#q of the image data DATA correspondingto the channels CH have a value of 1 and all of the second mostsignificant bits HB<8>#1 to HB<8>#q of the image data DATA correspondingto the channels CH have a value of 0, only the fourth and sixth switchesSW4 and SW6 of the switches SW3, SW4, SW5, and SW6 included in theselector 4355 corresponding to the second most significant bits HB<8>#1to HB<8>#q may be turned on in response to the input code D<8> having avalue of 0. In this case, the third and fifth switches SW3 and SW5 maymaintain a turn-off state. In this case, since the third and fifthswitches SW3 and SW5 maintain the turn-off state, global gamma voltagesA[1] to A[k] and A[2 k+1] to A[3k] output by the first and third subglobal ramps 432 a′ and 432 c′ are not output to the buffer 440.

In sum, the global gamma voltages A[1] to A[k] and A[2 k+1] to A[4k]output by the first, third, and fourth sub global ramps 432 a′, 432 c′,and 432 d′ in the horizontal period are not output to the buffer 440.

Accordingly, in order to prevent unnecessary power consumption due tothe operation of the first, third, and fourth sub global ramps 432 a′,432 c′, and 432 d′ in the corresponding horizontal period, the rampcontroller 434′ may generate the ramp control signal RCS_1 for turningoff the operation of the first, third, and fourth sub global ramps 432a′, 432 c′, and 432 d′. In this case, the global ramp 432 may turn offthe operation of the first, third, and fourth sub global ramps 432 a′,432 c′, and 432 d′ based on the ramp control signal RCS_1 provided fromthe ramp controller 434′.

As still another example, referring to FIG. 13C, when all of the mostsignificant bits HB<9>#1 to HB<9>#q of the image data DATA correspondingto the channels CH have a value of 0, only the second switch SW2 of theswitches SW1 and SW2 included in the selector 4356 corresponding to themost significant bits HB<9>#1 to HB<9>#q may be turned on in response tothe input code D<9> having a value of 0. In this case, the first switchSW1 may maintain a turn-off state. In this case, since the first switchSW1 maintains the turn-off state, the global gamma voltages A[1] toA[2k] output by the first and second sub global ramps 432 a′ and 432 b′are not output to the buffer 440.

In addition, when all of the second most significant bits HB<8>#1 toHB<8>#q of the image data DATA corresponding to the channels CH have avalue of 1, the third and fifth switches SW3 and SW5 among the switchesSW3, SW4, SW5, and SW6 included in the selector 4355 corresponding tothe second most significant bits HB<8>#1 to HB<8>#q may be turned on inresponse to the input code D<8> having a value of 1. In this case, thefourth and sixth switches SW4 and SW6 may maintain a turn-off state. Inthis case, since the fourth and sixth switches SW4 and SW6 maintain theturn-off state, the global gamma voltages [k+1] to A[2k] and A[3 k+1] toA[4k] output by the second and fourth sub global ramps 432 b′ and 432 d′are not output to the buffer 440.

In sum, the global gamma voltages A[1] to A[2k] A[3 k+1] to A[4k] outputby the first, second, and fourth sub global ramps 432 a′, 432 b′, and432 d′ in the corresponding horizontal period are not output to thebuffer 440.

Accordingly, in order to prevent unnecessary power consumption due tothe operation of the first, second, and fourth sub global ramps 432 a′,432 b′, and 432 d′ in the corresponding horizontal period, the rampcontroller 434′ may generate the ramp control signal RCS_1 for turningoff the operation of the first, second, and fourth sub global ramps 432a′, 432 b′, and 432 d′. In this case, the global ramp 432 may turn offthe operation of the first, second, and fourth sub global ramps 432 a′,432 b′, and 432 d′ based on the ramp control signal RCS_1 provided fromthe ramp controller 434′.

As still another example, referring to FIG. 13D, when all of the mostsignificant bits HB<9>#1 to HB<9>#q of the image data DATA correspondingto the channels CH have a value of 0 and all of the second mostsignificant bits HB<8>#1 to HB<8>#q of the image data DATA correspondingto the channels CH have a value of 0, the fourth and sixth switches SW4and SW6 among the switches SW3, SW4, SW5, and SW6 included in theselector 4355 corresponding to the second most significant bits HB<8>#1to HB<8>#q may be turned on in response to the input code D<8> having avalue of 0. In this case, the third and fifth switches SW3 and SW5 maymaintain a turn-off state. In this case, since the third and fifthswitches SW3 and SW5 maintain the turn-off state, the global gammavoltages A[1] to A[k] and A[2 k+1] to A[3k] output by the first andthird sub global ramps 432 a′ and 432 c′ are not output to the buffer440.

In sum, the global gamma voltages A[1] to A[3k] output by the first tothird sub global ramps 432 a′, 432 b′, and 432 c′ in the correspondinghorizontal period are not output to the buffer 440.

Accordingly, in order to prevent unnecessary power consumption due tothe operation of the first to third sub global ramps 432 a′, 432 b′, and432 c′ in the corresponding horizontal period, the ramp controller 434′may generate the ramp control signal RCS_1 for turning off the operationof the first to third sub global ramps 432 a′, 432 b′, and 432 c′. Inthis case, the global ramp 432 may turn off the operation of the firstto third sub global ramps 432 a′, 432 b′, and 432 c′ based on the rampcontrol signal RCS_1 provided from the ramp controller 434′.

FIG. 14 is a block diagram illustrating a display device according toembodiments of the disclosure.

Referring to FIGS. 1 and 14 , the display device 1000′ of FIG. 14 issubstantially the same or similar to the display device 1000 of FIG. 1except for a configuration in which a timing controller 200′ includes aramp controller 434″ and the ramp controller 434″ generates a rampcontrol signal RCS_2 by comparing the most significant bits of imagedata (the image data DATA of FIG. 3 ) and provides the ramp controlsignal RCS_2 to a data driving circuit 400′. Therefore, repetitivedescription is omitted.

The foregoing detailed description illustrates and describes thedisclosure. In addition, the foregoing description merely shows anddescribes preferred embodiments of the disclosure, and as describedabove, the disclosure may be used in various other combinations,modifications, and environments, and the disclosure may be changed ormodified within the scope of the concept of the disclosure disclosed inthis specification, the scope equivalent to the disclosed disclosure,and/or the skill or knowledge in the art. Accordingly, the detaileddescription of the disclosure is not intended to limit the disclosure tothe disclosed embodiments. Also, the appended claims should be construedas including other embodiments.

What is claimed is:
 1. A data driving circuit, comprising: adigital-analog converter to receive image data of a digital format, toreceive a reference voltage to generate a plurality of gamma referencevoltages based on the reference voltage, and to convert the image dataof the digital format into analog data signals of an analog format basedon a portion of the plurality of gamma reference voltages, wherein thedigital-analog converter comprises: a plurality of gamma decoders togenerate a plurality of global gamma reference voltages, each of theplurality of global gamma reference voltages being generated based on atleast some of the plurality of gamma reference voltages; and a decoderto output one of the plurality of global gamma reference voltagescorresponding to the image data of the digital format to generate theanalog data signals, and wherein at least some of the plurality of gammadecoders are turned off while remaining gamma decoders among theplurality of gamma decoders except for the at least some of theplurality of gamma decoders maintain a turn-on state.
 2. The datadriving circuit according to claim 1, wherein the at least some of theplurality of gamma decoders are turned off based on the image data ofthe digital format.
 3. The data driving circuit according to claim 2,further comprising a ramp controller to generate a ramp control signalby comparing most significant bits of the image data of the digitalformat, wherein the at least some of the plurality of gamma decoders areturned off based on the ramp control signal.
 4. The data driving circuitaccording to claim 2, further comprising a ramp controller to generate aramp control signal by comparing most significant bits of the image dataof the digital format, and comparing second most significant bits of theimage data of the digital format, wherein the at least some of theplurality of gamma decoders are turned off based on the ramp controlsignal.
 5. The data driving circuit according to claim 1, furthercomprising a voltage divider to generate the plurality of gammareference voltages based on the reference voltage.
 6. The data drivingcircuit according to claim 1, further comprising a global ramp includingthe plurality of gamma decoders.
 7. A method of driving a data drivingcircuit, the method comprising: obtaining image data of a digitalformat; generating a plurality of gamma reference voltages based on areference voltage by a plurality of gamma decoders included in the datadriving circuit; generating a plurality of global gamma referencevoltages, wherein each of the plurality of global gamma referencevoltages is generated based on a portion of the plurality of gammareference voltages; outputting one of the plurality of global gammareference voltages corresponding to the image data of the digitalformat; converting the image data of the digital format into analog datasignals based on the one of the plurality of global gamma referencevoltages; and turning off at least some of the plurality of gammadecoders while maintaining remaining gamma decoders among the pluralityof gamma decoders except for the at least some of the plurality of gammadecoders in a turn-on state.
 8. The method of claim 7, wherein the atleast some of the plurality of gamma decoders are turned off based onthe image data of the digital format.
 9. The method of claim 7, furthercomprising comparing most significant bits of the image data of thedigital format.
 10. The method of claim 9, wherein a ramp control signalis generated by comparing the most significant bits of the image data ofthe digital format.
 11. The method of claim 9, further comprisingcomparing second most significant bits of the image data of the digitalformat.
 12. The method of claim 11, wherein a ramp control signal isgenerated by comparing the most significant bits of the image data ofthe digital format and by comparing the second most significant bits ofthe image data of the digital format.